Rotary indexing table having a direct drive of the transport cam

ABSTRACT

The present invention relates to a rotary index table comprising a plate, which has drivers that engage with a drive groove of a cam barrel, wherein the plate can be driven by means of the cam barrel to carry out a rotational movement about a rotational axis which in turn can be driven by means of a motor to carry out a rotational movement about the longitudinal axis thereof, and wherein the motor directly drives the cam barrel.

The present invention relates to a rotary indexing table having a plate which has drivers engaging into a driving groove of a barrel cam. The plate is drivable via a barrel cam to make a rotary movement about an axis of rotation which is in turn drivable by a motor to make a rotational movement about its longitudinal axis.

Such rotary indexing tables are widely used, inter alia in assembly technology and automation technology. Workpieces are, for example, arranged on the plate which are set into continuous or clocked rotational movements for their machining and/or assembly. In this respect, the precision of the rotary indexing table is of special significance so that the workpiece always has well-defined positions/orientations relative to the assembly tools/machining tools. The precision of the apparatus results from the accuracy with which the plate can adopt the individual machining positions as well as from the precision of the rotational movement of the plate between the machining positions.

It is therefore an object of the present invention to provide a rotary indexing table which allows a reliable and precise rotational movement of the plate.

This object is satisfied by a rotary indexing table having the features of claim 1.

The rotary indexing table in accordance with the invention of the initially named kind is characterized in that the motor directly drives the barrel cam. A direct drive is to be understood such that no transmission is arranged between the motor and the barrel cam. The motor is, for example, flanged directly to the barrel cam (transport cam) or is only connected thereto by a shaft. The friction losses which always occur in the interior of a transmission are thereby avoided. In addition, any clearance in the transmission has a disadvantageous effect on the precision of the rotary indexing table. Such a transmission therefore has to be designed with low clearance, which is only possible with a large effort and is therefore expensive. In other words, the control of the barrel cam is simplified and made more precise by the direct drive, i.e. by the omission of a transmission and by a drive torque transfer from the motor to the barrel cam without “diversions”.

Further embodiments of the present invention are set forth in the description, in the drawings and in the dependent claims.

A compact construction of simple design provides a coaxial arrangement of the barrel cam and of the motor.

In accordance with a further embodiment of the present invention, the motor is an asynchronous motor. This embodiment is in particular suitable for rotary indexing tables in which cost factors play a role and compromises can be made in the precision of the rotational movement of the plate. These compromises can be minimized by a suitable regulation of the asynchronous motor.

Provision can be made that the motor is a torque motor which directly drives the barrel cam. Torque motors are—in simplified terms—large (multi-pole) motors optimized for high torques and having a hollow shaft. As a rule, they deliver comparatively small rotational drive speeds. These properties are particularly suitable for a rotary indexing table since usually no high rotational speeds of the turntable are required, but they should normally be driven with a high driving torque. Direct drives of a turntable by means of a torque motor are admittedly known; however, such rotary indexing tables are special designs which are only used in specific application fields. In the present embodiment, the drive of the turntable takes place via the barrel cam which is in turn driven by a torque motor. On a drive of the barrel cam by a torque motor, existing design principles can largely be made use of. Only the drive of the barrel cam is modified/replaced.

In accordance with a further development of this embodiment, the barrel cam has a prolongation which substantially has the diameter of the barrel cam and has the functional components of the torque motor. The barrel cam itself thus comprises a section which is not reduced in cross-section in comparison with the section having the driving groove. In other words, the prolongation forms an extension section of the barrel cam without a driving groove. The prolongation is simultaneously the rotor of the torque motor, i.e. the prolongation of the barrel cam has the components required for the operation of the torque motor. These components can be magnets or coils, for example.

The described construction represents the “most direct” construction of a direct drive of the barrel cam since a drive shaft for transmitting the driving torque from the motor to the barrel cam can also be dispensed with.

The invention will be described in the following purely by way of example with reference to advantageous embodiments and to the drawings. There are shown:

FIG. 1 a schematic view of an embodiment of a rotary indexing table in accordance with the invention from above; and

FIG. 2 a cross-section through a further embodiment of a rotary indexing table in accordance with the invention.

FIG. 1 schematically shows a rotary indexing table 10 which has a turntable 12 on which workpieces can be spanned for machining and/or assembly. The turntable 12 is driven by a barrel cam 14 to make a rotational movement about an axis of rotation R which extends perpendicular to the plane of the Figure. To transmit a drive movement of the barrel cam 14, which is a rotation of the barrel cam 14 about an axis of rotation R′ perpendicular to the axis of rotation R, onto the turntable 12, the latter has drivers (not shown in FIG. 1) which engage in a form known per se into a driving groove (not shown in FIG. 1) having a constant or varying pitch and running spirally about the barrel cam 14.

The barrel cam 14 is rotationally fixedly connected to a drive shaft 16. The drive shaft 16 is simultaneously the output shaft of a motor 18 which is, for example, electrically driven.

In the rotary indexing table 10, the barrel cam 14 and the motor 18 are arranged coaxially, i.e. both the motor 18 and the drive shaft 16 as well as the barrel cam 14 rotate about the common axis of rotation R′ in operation.

It can be seen from FIG. 1 that the drive of the barrel cam 14 takes place in a direct manner, i.e. without a transmission interposed between the motor 18 and the barrel cam 14. Only the drive shaft 16 is provided to transmit a driving torque between the two named components.

In principle any motor—also of a non-electric construction—can be used as the motor 18, such as asynchronous motors or synchronous motors.

FIG. 2 shows a cross-section through a further embodiment 10′ of the rotary indexing table. It can be recognized in the left hand part of the drawing how a driver 20 of the turntable 12 engages into a driving groove 22 of the barrel cam 14. The representation of this known drive concept is only shown in highly simplified form.

The right hand part of FIG. 2 comprises the drive components of the barrel cam 14. In contrast to the embodiment shown in FIG. 1, the drive of the rotary indexing table 10′ has no drive shaft 16. The barrel cam 14 rather itself forms a part of the motor 18′ which is made as a torque motor. The barrel cam 14 has (electric) magnets 24 at an extension section A which cooperate with coils 26 of the torque motor 18′. In other words, the extension section A is the rotor of the torque motor 18′ which is directly connected to a section B of the barrel cam 14 having the driving groove 22. The sections A, B are consequently integral components of the barrel cam 14. The section B of the barrel cam 14 can also be called—relative to the extension section A—an extension of the rotor of the torque motor 18′. The extension section A has substantially the same diameter as the section B of the barrel cam 14 provided with the driving groove 22.

The embodiment of the drive of the rotary indexing table 10′ shown schematically in FIG. 2 is characterized by a compact construction and a precise drive of the barrel cam 14. Expensive transmission elements suffering from friction/clearance are not used.

REFERENCE NUMERAL LIST

-   10, 10′ rotary indexing table -   12 turntable -   14 barrel cam -   16 drive shaft -   18 motor -   18′ torque motor -   20 driver -   22 driving groove -   24 magnet -   26 coil -   R, R′ axis of rotation -   A extension section -   B groove section 

1. A rotary indexing table having a plate (12) which has drivers (20) engaging into a driving groove of a barrel cam (14), wherein the plate (12) can be driven via the barrel cam (14) to make a rotary movement about an axis of rotation (R) which is in turn drivable by a motor (18, 18′) to make a rotational movement about its longitudinal axis (R′), wherein the motor (18, 18′) directly drives the barrel cam (14).
 2. A rotary indexing table in accordance with claim 1, wherein the barrel cam (14) and the motor (18, 18′) are coaxially arranged.
 3. A rotary indexing table in accordance with claim 1, wherein the motor (18, 18′) is an asynchronous motor.
 4. A rotary indexing table in accordance with claim 1, wherein the motor is a torque motor (18′) which directly drives the barrel cam (14).
 5. A rotary indexing table in accordance with claim 4, wherein the barrel cam (14) has a prolongation (A) which has substantially the diameter of the barrel cam (14) and has the functional components (24) of the torque motor. 